Two calcineurin B-like calcium sensors, interacting with protein kinase CIPK23, regulate leaf transpiration and root potassium uptake in Arabidopsis

Calcium signalling involves sensor proteins that decode temporal and spatial changes in cellular Ca2+ concentration. Calcineurin B-like proteins (CBLs) represent a unique family of plant calcium sensors that relay signals by interacting with a family of protein kinases, designated as CBL-interacting protein kinases (CIPKs). In a reverse genetic screen for altered drought tolerance, we identified a loss-of-function allele of CIPK23 as exhibiting a drought-tolerant phenotype. In the cipk23 mutant, reduced transpirational water loss from leaves coincides with enhanced ABA sensitivity of guard cells during opening as well as closing reactions, without noticeable alterations in ABA content in the plant. We identified the calcium sensors CBL1 and CBL9 as CIPK23-interacting proteins that targeted CIPK23 to the plasma membrane in vivo. Expression analysis of the CIPK23, CBL1 and CBL9 genes suggested that they may function together in diverse tissues, including guard cells and root hairs. In addition, expression of the CIPK23 gene was induced by low-potassium conditions, implicating a function of this gene product in potassium nutrition. Indeed, cipk23 mutants displayed severe growth impairment on media with low concentrations of potassium. This phenotype correlates with a reduced efficiency of K+ uptake into the roots. In support of the conclusion that CBL1 and CBL9 interact with and synergistically serve as upstream regulators of CIPK23, the cbl1 cbl9 double mutant, but not the cbl1 or cbl9 single mutants, exhibit altered phenotypes for stomatal responses and low-potassium sensitivity. Together with the recent identification of the potassium channel AKT1 as a target of CIPK23, these results imply that plasma membrane-localized CBL1- and CBL9-CIPK23 complexes simultaneously regulate K+ transport processes in roots and in stomatal guard cells.     

Calcineurin B‐like protein CBL10 directly interacts with AKT1 and modulates K+ homeostasis in Arabidopsis

Potassium transporters and channels play crucial roles in K⁺ uptake and translocation in plant cells. These roles are essential for plant growth and development. AKT1 is an important K⁺ channel in Arabidopsis roots that is involved in K⁺ uptake. It is known that AKT1 is activated by a protein kinase CIPK23 interacting with two calcineurin B‐like proteins CBL1/CBL9. The present study showed that another calcineurin B‐like protein (CBL10) may also regulate AKT1 activity. The CBL10‐over‐expressing lines showed a phenotype as sensitive as that of the akt1 mutant under low‐K⁺ conditions. In addition, the K⁺ content of both CBL10‐over‐expressing lines and akt1 mutant plants were significantly reduced compared with wild‐type plants. Moreover, CBL10 directly interacted with AKT1, as verified in yeast two‐hybrid, BiFC and co‐immunoprecipitation experiments. The results of electrophysiological analysis in both Xenopus oocytes and Arabidopsis root cell protoplasts demonstrated that CBL10 impairs AKT1‐mediated inward K⁺ currents. Furthermore, the results from the yeast two‐hybrid competition assay indicated that CBL10 may compete with CIPK23 for binding to AKT1 and negatively modulate AKT1 activity. The present study revealed a CBL‐interacting protein kinase‐independent regulatory mechanism of calcineurin B‐like proteins in which CBL10 directly regulates AKT1 activity and affects ion homeostasis in plant cells.     

Disruption of the Arabidopsis thaliana inward-rectifier K+ channel AKT1 improves plant responses to water stress

The Arabidopsis thaliana inward-rectifier K(+) channel AKT1 plays an important role in root K(+) uptake. Recent results show that the calcineurin B-like (CBL)-interacting protein kinase (CIPK) 23-CBL1/9 complex activates AKT1 in the root to enhance K(+) uptake. In addition, this CIPK-CBL complex has been demonstrated to regulate stomatal movements and plant transpiration. However, a role for AKT1 in plant transpiration has not yet been demonstrated. Here we show that disruption of AKT1 conferred an enhanced response to water stress in plants. Experiments performed in hydroponics showed that, when water potential was diminished by adding polyethylene glycol, akt1 adult plants lost less water than wild-type (WT) plants. Under long-term water stress in soil, adult akt1 plants displayed lower transpiration and less water consumption than WT plants. Finally, akt1 stomata closed more efficiently in response to ABA. Such results were also observed in cipk23 plants. The similar responses shown by cipk23 and akt1 plants to water stress denote that the regulation of AKT1 by CIPK23 may also take place in stomata and has a negative impact on plant performance under water stress conditions.     

A DExD/H box RNA helicase is important for K+ deprivation responses and tolerance in Arabidopsis thaliana

The molecular mechanism for sensing and transducing the stress signals initiated by K(+) deprivation in plants remains unknown. Here, we found that the expression of AtHELPS, an Arabidopsis DExD/H box RNA helicase gene, was induced by low-K(+), zeatin and cold treatments, and downregulated by high-K(+) stress. To further investigate the expression pattern of AtHELPS, pAtHELPS::GUS transgenic plants were generated. Histochemical staining indicated that AtHELPS is mainly expressed in the young seedlings and vascular tissues of leaves and roots. Using both helps mutants and overexpression lines, we observed that, in the low-K(+) condition, AtHELPS affected Arabidopsis seed germination and plant weight. Interestingly, the mRNA levels of AKT1, CBL1/9 and CIPK23 in the helps mutants were much higher than in the overexpression lines under low-K(+) stress. Moreover, under low-K(+) stress, the helps mutants displayed increased K(+) influx, whereas the overexpression line of AtHELPS had a lower flux rate in the roots by the noninvasive micro-test technique. Taken together, these results provide information for the functional analysis of plant DEVH box RNA helicases, and suggest that AtHELPS, as an important negative regulator, plays a role in K(+) deprivation stress.     

Alternative complex formation of the Ca-regulated protein kinase CIPK1 controls abscisic acid-dependent and independent stress responses in Arabidopsis

Intracellular release of calcium ions belongs to the earliest events in cellular stress perception. The molecular mechanisms integrating signals from different environmental cues and translating them into an optimized response are largely unknown. We report here the functional characterization of CIPK1, a protein kinase interacting strongly with the calcium sensors CBL1 and CBL9. Comparison of the expression patterns indicates that the three proteins execute their functions in the same tissues. Physical interaction of CIPK1 with CBL1 and CBL9 targets the kinase to the plasma membrane. We show that, similarly to loss of CBL9 function, mutation of either CBL1 or CIPK1 renders plants hypersensitive to osmotic stress. Remarkably, in contrast to the cbl1 mutant and similarly to the cbl9 mutant, loss of CIPK1 function impairs abscisic acid (ABA) responsiveness. We therefore suggest that, by alternative complex formation with either CBL1 or CBL9, the kinase CIPK1 represents a convergence point for ABA-dependent and ABA-independent stress responses. Based on our genetic, physiological and protein-protein interaction data, we propose a general model for information processing in calcium-regulated signalling networks.     

Heteromeric AtKC1��AKT1 Channels in Arabidopsis Roots Facilitate Growth under K+-limiting Conditions

Plant growth and development is driven by osmotic processes. Potassium represents the major osmotically active cation in plants cells. The uptake of this inorganic osmolyte from the soil in Arabidopsis involves a root K⁺ uptake module consisting of the two K⁺ channel α-subunits, AKT1 and AtKC1. AKT1-mediated potassium absorption from K⁺-depleted soil was shown to depend on the calcium-sensing proteins CBL1/9 and their interacting kinase CIPK23. Here we show that upon activation by the CBL·CIPK complex in low external potassium homomeric AKT1 channels open at voltages positive of E_K, a condition resulting in cellular K⁺ leakage. Although at submillimolar external potassium an intrinsic K⁺ sensor reduces AKT1 channel cord conductance, loss of cytosolic potassium is not completely abolished under these conditions. Depending on channel activity and the actual potassium gradients, this channel-mediated K⁺ loss results in impaired plant growth in the atkc1 mutant. Incorporation of the AtKC1 subunit into the channel complex, however, modulates the properties of the K⁺ uptake module to prevent K⁺ loss. Upon assembly of AKT1 and AtKC1, the activation threshold of the root inward rectifier voltage gate is shifted negative by approximately −70 mV. Additionally, the channel conductance gains a hypersensitive K⁺ dependence. Together, these two processes appear to represent a safety strategy preventing K⁺ loss through the uptake channels under physiological conditions. Similar growth retardation phenotypes of akt1 and atkc1 loss-of-function mutants in response to limiting K⁺ supply further support such functional interdependence of AKT1 and AtKC1. Taken together, these findings suggest an essential role of AtKC1-like subunits for root K⁺ uptake and K⁺ homeostasis when plants experience conditions of K⁺ limitation.Fundamental plant functions such as control of the membrane potential, osmo-regulation, and turgor-driven growth and movements are based on the availability to gain high cellular potassium concentrations (1). The absorption of this inorganic osmolyte from the soil by the root therefore represents a pivotal process for plant life. Classical experiments by Epstein et al. in 1963 (2) described K⁺ root uptake as a biphasic process mediated by two uptake mechanisms: high affinity potassium transport with apparent affinities of ∼20 μm and a low affinity transport system with K_m values in the millimolar range. During the last decades several molecular components of potassium transport systems have been identified and functionally characterized in plants (3, 4). Mutant analyses, heterologous expression, as well as radiotracer uptake experiments characterized the K⁺ channels AKT1·AtKC1 and members of the HAK·KT·KUP family as major components of the Arabidopsis thaliana root-localized potassium transport system (5–9). In this study we focused on AKT1 and AtKC1, members of the Arabidopsis Shaker-like K⁺ channel family. AKT1 is a voltage-dependent inward-rectifying K⁺ channel mediating potassium uptake over a wide range of external potassium concentrations (10–15). Root cells of the akt1-1 loss-of-function mutant completely lack inward rectifying K⁺ currents (12). As a consequence the growth of akt1-1 seedlings is strongly impaired on low potassium medium (100 μm and less) (11, 12, 15). Rescue of yeast growth on 20 μm K⁺ and patch clamp experiments (16, 17) directly demonstrated that plant inward rectifying K⁺ channels are capable of serving as high affinity potassium uptake transporters. AtKC1 shares its expression pattern with AKT1 (18–20). AtKC1 α-subunits, however, neither form functional channels in akt1-1 knock-out plants nor in heterologous expression systems. In contrast to root cells of akt1-1 loss of function mutants, root protoplasts of AtKC1 null mutants (atkc1-f) still exhibit inward rectifying potassium currents most likely derived from homomeric AKT1 tetramers (20). Inward K⁺ currents in this atkc1-f mutant were characterized by a more positive activation voltage. These data suggested that the AtKC1 α-subunits do not form K⁺ channels per se but modulate the properties of the AKT1·AtKC1 heterocomplex (20–22). Previously, two groups in their ground-breaking studies demonstrated that AKT1 is activated by the CBL²-interacting, serine/threonine kinase, CIPK23, particularly under low K⁺ conditions (23, 24). CIPK23 itself was shown to be activated by the two calcineurin B-like proteins, CBL1 and 9, acting in a Ca²⁺-dependent manner upstream of CIPK23 (25, 26). Genetic disruption of these elements resulted in transgenic plants exhibiting a phenotype comparable with that of the AKT1 loss of function mutant. This regulatory system, based on a calcium sensor, a protein kinase, and a K⁺ channel, was functionally reconstituted in Xenopus oocytes (23, 24, 27), suggesting that these elements are essential and sufficient to operate as a low K⁺-sensitive potassium uptake system. Here we report on the physiological properties of the heteromeric K⁺ uptake module formed by the predominant root potassium uptake channel subunits, AKT1 and AtKC1 and its regulating kinase complex, CBL1 and CIPK23. Our studies show that the physical interaction of the CBL1·CIPK23 complex is specific for AKT1 channels and does not involve the AtKC1 subunit. AKT1 possesses a K⁺ (absence) sensor affecting channel activity at submillimolar K⁺ concentrations by strongly reducing its maximal cord conductance. Despite this K⁺ sensor, upon activation, AKT1 homomeric channels were shown to represent a potassium leak at low external potassium concentrations. Integration of AtKC1 into the K⁺ uptake module, however, prevented potassium loss by modulating both the voltage sensor and conductance in the channel complex. Moreover, activation of the AKT1-like maize channel ZMK1 by CBL1·CIPK23 suggests a conserved interaction and regulation across monocot and dicotyledonous plant species. Our biophysical studies as well as growth assays with plant mutant lines lacking the respective channels underline that acquisition of potassium under limiting K⁺ conditions is mediated via the root AKT1·AtKC1 K⁺ uptake channel complex.     

拟南芥钾离子吸收、转运及低钾胁迫的分子机理研究进展

钾(K)作为植物所需的3种大量元素之一,参与体内诸多的生理和生化过程,对于植物的生长和发育极其重要。目前,国内外学者对植物吸收、运输和利用K⁺的研究已有一定深度,尤其以模式植物拟南芥(Arabidopsis thaliana (L.) Heynh.)为研究对象。其中,与K⁺吸收、转运相关的离子通道和转运蛋白一直都是研究热点。本文综合近年来国内外相关研究进展,主要阐述K⁺通道和转运蛋白,K⁺的吸收和运输,类钙调磷酸酶(Calcineurin B-Like,CBL)-CBL相互作用蛋白激酶(CBL-Interacting protein kinase,CIPK)信号途径,参与该信号转导的一些小信号分子,对K⁺研究方面存在的问题进行了总结,并对未来的研究方向进行了展望。